Technological challenges in manufacturing of vacuum gauge thermionic cathode using thick-film technology

Optical microscope imaging results: a) top view of the structure with the thickness testing trajectory (red line), b) thickness profile of the tested structure according to the set trajectory

Fig. 3.

Samples: a) before firing, b) after firing using different two-stage temperature profile

Structures of platinum bridge directly on Al2O3 substrate before firing: a) 1 SVM layer, b) 2 SVM layers

Structures of platinum bridge directly on alundum substrate after firing in a chamber furnace: a) 1 SVM layer, b) 2 SVM layers

Structures of platinum bridge directly on alundum substrate after belt furnace firing: a) 1 SVM layer, b) 2 SVM layers

Matrix of platinum bridges with different geometries: a) after application of carbon layer, b) after application of platinum layer, c) after firing

Platinum bridge structures on ceramic supports: a) design pattern, b) fired structures without the lamination process, c) fired structures with the lamination process before firing

One-sided structures: a) design pattern, b) unfired structures, c) fired structures

LTCC platinum bridges: a) after screen printing of the platinum layer, b) after the firing process

Surface characterization using SEM/Ga-FIB of FEI Helios Nanolab 600i (operating voltage and current of 1 kV and 86 μA, respectively) for Al2O3 samples: a) without etching and after etching for: b) 5 min, c) 10 min, d) 15 min, e) 30 min

Fig. 12.

Surface roughness profile of alundum substrates: a) before etching, b) after etching in KOH for 30 min and ?380 °C

Al2O3 wet etching process in KOH: a) structures before etching, b) acceptable result, c) unacceptable result

Schematic diagram of the bench for thermal measurements of a platinum thermionic cathode

Calibration curves of the measurement station using a thermal imaging camera

Temperature dependence of platinum planar structures as a function of applied electrical power

Experimental setup (emission performance)

Emission current vs thermionic cathode power

Results of thermal measurements for planar platinum structures

Supply current I [A]	Supply voltage U [V]	Power P [W]	Structure temp. Without shutter T [°C]	Structure temp. with shutter T_Si [°C] = T·0.66925
Measurement with rapid temperature rise
0.33	3.05	1.01	150	100.39
0.39	3.94	1.54	200	133.85
0.46	5.43	2.48	300	200.78
0.50	6.83	3.41	400	267.70
0.55	8.42	4.63	500	334.63
Measurement with slow temperature rise
0.35	2.847	0.99645	150	100.39
0.39	3.44	1.33	200	133.85
0.46	4.73	2.15	300	200.78
0.51	6.02	3.06	400	267.70
0.56	7.52	4.24	500	334.63
0.611	9.00	5.50	600	401.55
0.66	10.70	7.09	700	468.48

Calibration measurements for silicon shutter bench

Supply current I [A]	Supply voltage U [V]	Power P [W]	Structure temp. without shutter T [°C]	Structure temp. with shutter T_Si [°C]	Loss rate T_Si/T [%]
0.33	3.05	1.0065	150	97	64.7
0.386	3.94	1.52084	201	135	67.2
0.45	5.43	2.4435	300	206	68.7
0.5	7.02	3.51	402	272	67.1
				Mean	66.925
				Standard deviation	1.654

eISSN:: 2083-134X
Język:: Angielski

Częstotliwość wydawania:: 4 razy w roku
Dziedziny czasopisma:: Materials Sciences, other, Nanomaterials, Functional and Smart Materials, Materials Characterization and Properties

Kanał RSS czasopisma

Technological challenges in manufacturing of vacuum gauge thermionic cathode using thick-film technology

Data publikacji: 22 maj 2024

Zakres stron: 126 - 139

Otrzymano: 05 lut 2024

Przyjęty: 11 kwi 2024

DOI: https://doi.org/10.2478/msp-2024-0007

Słowa kluczowe
alundum, wet etching, vacuum gauge, SVM, thick-film

© 2024 Laura Jasińska et al., published by Sciendo

This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.

Fig. 1.